KR100910730B1 - Buoy-type deckroad - Google Patents

Abstract

A float for a deck road is provided to reduce shaking due to wave by forming a cylindrical wing piece at the lower curved surface of a float body and to function as a promenade and a road by installing a base, a safety guardrail, an upper plate deck in 3-dimensional float. A float for a deck road comprises a 3-dimensional float, a base, an upper plate deck, and a safety guardrail. The 3-dimensional float comprises a float body(14), a wing piece(30), and a loop(16). The loop is formed in the longitudinal direction of the float. The rope is bound to the side of the float through the loop. A float member is formed inside the float body. The float body is composed of an upper surface(11), a lower surface and a side surface. The upper surface, the lower surface and the side surface are arranged in a flat shape.

Description

Buoy-type deckroad

The present invention relates to a buoyant waterside deck rod installed on the water surface of the sea surface or the inner water surface, and more specifically, the base base 40 and the safety railing 60 and the upper plate based on the three-dimensional buoy 10 which can prevent wave shaking. By installing the deck 50 to be used as a moving path and walkway of a farm or aquatic ecosystem, it is safer than those using conventional buoys, and is easy to install and greatly reduces maintenance and maintenance costs. It is about.

Buoys are also commonly referred to as buoys or buoys. It is installed to direct the route or to warn the existence of nautical hazards such as reefs and sunken ships in order to help the safe navigation of ships. In particular, it is called a back buoy that lights are installed for night use. The meaning of a buoy or a buoy varies depending on the color and shape of the buoy or the color and quality of the buoy.

Buoys are also used to indicate the location of objects in water, such as fishing gear and anchors. The simplest buoys used for this purpose include a flagpole on a large moxibustion in the daytime, a weight on the bottom, a flag on the upper side, and a lamp on a wooden frame at night, or an iron and moxa frame. There is a light on with the battery on. But this is not noticeable at very long distances, so radio buoys or radio-reflective buoys are used. Radio buoys detect the direction of radio signals emitted from the buoy by the radio wave direction detector on the ship, and radio-reflective buoys are equipped with a radio reflector at the top of the buoy to reflect radio waves emitted from the radar on the ship. By coming in to find out its location.

However, buoys have recently been put to practical use and are widely used for cage farms, floating houses, decks for aquatic ecosystem learning, and buoy bridges.

As such, Prior Art 20-0323487 discloses a fishing boat using a buoy. In addition, the prior invention registration room 20-0390426 also discloses a water play equipment using a buoy.

Although the preceding inventions disclose fishing boats and play equipment using buoyancy buoyancy, it is merely using the basic principle that buoyancy is generated in water because the material of buoy is lower than the specific gravity of water. It shows that it only uses the features that appear in the group.

In addition, the buoy used for decks, buoy legs, fish cages, etc. for aquatic ecosystem learning is wrapped around the styrofoam with a cord and put a plate of a certain area on top of it to allow people to move.

Therefore, if there is an influence on the load of the buoy according to the movement of the person, the cylindrical buoy is applied to the buoy of the water as a whole because the force of the water is applied to the buoy. In the absence of a person again, a recoil is applied to the buoy as much as the load of the person, resulting in a continuous wave motion. These ongoing wave movements have significantly reduced the stability and safety of decks, buoy bridges and fishing cage buoys for aquatic learning.

In addition, water decks, water bridges, dams or lakes using water buoys have always been pointed out as problems due to the fluctuations of up, down, left and right due to waves, ie waves caused by waves.

So, in order to solve the problem of the shaking caused by the wave, generally use a fixed waterfront deck, the fixed waterfront deck has the advantage that there is no shaking, while the water is removed from the reservoir during installation and through the digging and additional work As a result, the process is complicated and costs a lot of construction costs.

In addition, the fixed water deck is not only inferior in accessibility and stability due to the change in water level, but also exposed to the problem that it is impossible to install in deep water.

The present invention has been devised to solve the above problems, the foundation base 40, the safety railing 60 and the upper deck (50) by installing a three-dimensional buoy 10 that can prevent the shaking of the fish farm Or to use as a walkway and walkway of aquatic ecosystem learning site to be safer than those using a conventional buoy, to provide an anti-shake buoyant waterfront deck rod that is easy to install and significantly reduced maintenance and maintenance costs. There is a purpose.

It solves the shortcomings and problems of the fixed waterside deck mentioned above, and it is a deck for buoyancy, buoyary bridge, buoy bridge for fishing cages, fishing house, floating bridge, dam (or buoy) for aquatic ecosystem learning using conventional buoys. In order to solve the problem that the water quality control deck or waterside deck is extremely shaken by wave waves, the three-dimensional buoy 10 is fixed to the base base 40 at regular intervals, and the top deck 50 is disposed thereon. ) To allow walking and to provide a buoyant waterside deck rod that is largely prevented by installing a safety handrail 60 for the safety of pedestrians. The three-dimensional buoy 10 forms a buoyancy body therein, the outside forms an upper surface, a lower surface and a side, and the lower curved surface of the buoy body to form a cylindrical wing piece to absorb the wave wave to prevent shaking It will provide a three-dimensional buoy (10).

As described above, using the anti-shaking three-dimensional buoy of the present invention, not only the shaking caused by the wave of the sea surface or the inner surface of the water and the wave due to the change of its own load is significantly reduced, but also of the waterside deck and fishing village using the buoy. It is possible to safely and stably move people on the waterway for fish farms and waterways for learning aquatic ecosystems, and the installation and manufacturing costs are significantly reduced.

In addition, there is an advantage that the structure of the waterway deck for learning the waterfront deck, aquaculture farms and aquatic ecosystems using the conventional buoys is remarkably simplified, thereby reducing the development cost.

The present invention relates to a buoyant waterside deck rod using a three-dimensional buoy floating in water, and more specifically to a buoyant waterside deck rod using a three-dimensional buoy that is safe even from severe wave fluctuations, such as a sea level or aquaculture farm, aquatic learning center, etc. It is related to the buoy waterside deck road that is installed in a mobile or mountain road, less shaking than using a conventional buoy, safe, inexpensive installation cost, and reduced maintenance and management costs.

Hereinafter, the present invention will be described in detail.

The present invention is invented to improve the disadvantage that the buoy is violently shaken in response to the wave phenomena caused by the change of its own load or the waves of the sea and the inner surface of the water buoyant to prevent the shake is remarkably prevented three-dimensional type A buoyant waterside deck rod using buoys.

1 shows a perspective view of the three-dimensional buoy of the present invention.

As shown in FIG. 1, the three-dimensional buoy 10 of the present invention is composed of a buoy body 14 and a cylindrical wing piece 30.

The buoy body 14 is made of a material such as press-fitting resin, plastic, polystyrene, polyurethane, or wood, stainless steel, etc., which is itself buoyant. Therefore, the buoy body 14 itself is buoyant, so it floats in water and the buoy body 14 may be formed in a form including a buoyancy body 15 therein. The reason for this is that when the buoy body 14 is a material having a small buoyancy or a material having a specific gravity greater than the buoyancy of fresh water and seawater, the buoyant body has a specific gravity lower than that of fresh water and seawater to generate buoyancy in the body. To form buoyancy.

The buoy body 14 is composed of an upper surface 11, a lower surface 12, and a side surface 13.

The reason why the buoy body is composed of an upper surface, a lower surface and a side surface is to be described in more detail because the buoy body can be expressed in various shapes.

In addition, the present invention has a strong resistance to wave shaking due to the shape of the buoy body described above. The upper and lower surfaces of the buoy body may have a flat, concave, or convex shape that is resistant to wave shaking.

In general, the buoy in the form of a drum had a morphological characteristic that can only respond very sensitive to waves.

However, in the present invention, the buoyant solid buoy has a buoy body itself having an upper surface, a lower surface, and a side surface as described above, and the upper surface and the lower surface have a flat, concave, or convex shape.

In addition, the upper and lower surfaces are circular, oval or rectangular in shape. However, the description in this form is merely described as such because of the limitations that cannot describe all forms. Thus, any shape, round, oval or rectangular, of different lengths and widths on the top and bottom surfaces is possible. Preferably the length is larger than the width, more preferably the ratio of length to width is preferably composed of 2: 1 or more.

And, the upper surface and the lower surface may differ in the area. The upper surface and the lower surface should be the same or similar in area, but preferably the larger area of the lower surface can reduce the influence of the wave due to the change of the load applied to the waves and buoys.

Due to the morphological characteristics of the upper and lower surfaces, it is possible to produce a three-dimensional shape that can significantly reduce the resistance due to the waves and reduce the influence of the wave due to the change of load.

More specifically described as follows.

The upper and lower surfaces of the body are connected by side surfaces. Therefore, if the lower surface is larger than the upper surface area is to form a bevel with respect to the horizontal plane.

This aspect of the oblique form will be described again, but even if the wave is pushed along the oblique side of the wave will have a significant effect of reducing the vibration energy of the wave. In other words, the vibrational energy of the wave is naturally absorbed to the side of the three-dimensional body as the wave caused by the sound is absorbed by the sound absorber.

In addition, as described above, the upper surface, the lower surface or the side surface of the buoy body may be formed in a flat, concave or convex shape.

The upper surface, the lower surface or the side surface is a general feature of the present invention in the flat form, but when it is in the concave or convex form, it exhibits the effect of reducing the wave energy due to the wave.

For example, waves generally have the properties of surface waves. The surface wave transmits kinetic energy in a direction perpendicular to the water while vibrating up, down, left and right with respect to the water surface. When the top, bottom or side surfaces of the three-dimensional buoy are concave or convex, the kinetic energy is easily obtained. This is because it also functions to pass.

Therefore, the characteristics of the present invention is to significantly reduce the kinetic energy of the wave in the geometric characteristics of such a buoy body.

And it will be described with respect to the cylindrical wing piece 30 connected to the lower curved surface of the buoy body which is the greatest feature of the present invention.

The cylindrical wing in the present invention is an entirely new one not found in the conventional buoys and is a breakthrough in which the technical idea of the present inventor is melted.

As shown in FIG. 1, the cylindrical wing piece connected to the lower curved surface of the buoy body is literally connected to the lower curved surface of the body and means a cylindrical wing piece of which the size of the peripheral circumference extends toward the end.

Cylindrical wing piece is attached with the modifier of cylindrical shape, but the characteristic description is that the inside of the wing piece is empty and the shape of the wing piece can have a cylindrical or conical shape.

In other words, the circumference of the connecting portion 31 of the wing piece connected to the buoy body may be the same or different than the circumference of the end portion 32 of the wing piece. It also means that the shape of the periphery of the tip of the wing piece itself may be different from the shape of the perimeter of the connecting piece of the wing piece that is connected to the buoy body.

Preferably, the circumference and the area of the tip of the blade piece are larger than the circumference and area of the blade piece. Thus, the wing piece is composed of a cylindrical shape that extends toward the end, thereby significantly reducing the wave phenomenon due to the change in the load acting on the buoy.

In addition, as shown in Figure 3, the shape of the end of the blade piece may be formed in a sawtooth curve (35). Forming such a form shows an effect of facilitating when the present buoy floats in water.

And another feature of the present invention is that the wing piece connected to the buoy body forms an acute angle with respect to the horizontal plane.

As shown in FIG. 3, the angle θ of the blade piece with respect to the horizontal plane forms an acute angle. Preferably, 15 ° to 70 ° serves to significantly reduce the shaking caused by the waves. This is because when the angle is maintained, the effect of the surface tension to be described later becomes maximum.

The interior 33 of the cylindrical wing piece is empty as can be seen from the word cylindrical.

Since the inside of the cylindrical wing piece is hollow, the present invention is a buoy that can significantly prevent the wave phenomenon caused by the shaking of the wave or the change of the load of the buoy itself.

I will explain the technical action.

As shown in FIG. 3, when the present invention floats a three-dimensional buoy in which shaking is suppressed, the three-dimensional buoy subsides slightly from the water due to the weight of the buoy itself. And when installing a structure such as the deck deck 50 and the safety railing 60 on the buoy buoy 10 will sink even more.

However, even if the three-dimensional buoy 10 is lowered, the inner space 34 of the wing piece of Figure 3 is filled with air, thereby generating a strong buoyancy. Air is about 780 times smaller than water. So air is the best buoyant body.

In addition, the air in the inner space of the blade pieces have a pressure equal to the atmospheric pressure. Therefore, even though the buoy body is forced by the external resistance, that is, the wave, by the action of the internal air of the wing piece, it has the force to maintain a constant height with respect to the surface of the water. That is, even if the wave is to transfer the kinetic energy to the buoy body, the buoy body itself has a function to maintain a stable by the air in the inner space of the wing piece is significantly reduced by the kinetic energy transmitted by the wave.

In addition, even if the load on the buoy body changes, for example, the load of the buoy consists of the weight of the buoy body itself and the weight of the top deck and safety rails installed on the upper surface of the buoy body. Even if the weight change applied to the upper surface of the buoy body, the fluctuation of the three-dimensional buoy 10 is significantly reduced by the action of the air in the inner space of the wing piece.

This principle, as we've seen in real life, can be easily pulled out of the water even when a load is applied to the gourd when the gourd is laid down and floated in the water. It is the same principle of operation.

In addition, the characteristic function of the present invention is generated when the three-dimensional buoy 10 is installed on the surface of the sea or the sea surface, the wing piece is kept submerged in the water surface and the sea surface. That is, the wing piece has a large contact area with the water surface or the sea surface. This large contact area acts as a surface tension between the water surface and the sea surface. This surface tension prevents the buoy from oscillating on the surface of the buoy when the buoy is externally applied, that is, even when the kinetic energy is transmitted by the waves, and also prevents the wave motion caused by the change of the buoy's load. . In other words, the surface tension of the water and the wing piece is to secure the buoy.

The anti-shake buoy according to the present invention has a function of reducing the resistance of the waves due to the shape of the three-dimensional buoy, buoyancy by the air inside the wing pieces, and surface tension due to the characteristics of the wing pieces' geometrical characteristics, It is a safe and stable buoy that significantly prevents the wave phenomenon caused by the change of the load of the buoy itself.

In addition, the material of the wing piece may be used as a material in a variety of durable. Preferably, the material of the wing piece itself may have a specific gravity smaller than that of fresh water or seawater, but if not, it does not significantly affect the present invention.

The material of the wing is also related to the surface tension. Therefore, plastics, polystyrene, polyurethane, wood, steel, stainless steel and the like can be used in various ways. However, it is preferable to use plastics with good durability.

In addition, the present invention is to provide a safe and stable buoy waterside deck rod by using the three-dimensional buoy that the shaking is suppressed.

As shown in Figure 4 the present invention is installed by connecting the base base 40 by the fastening means 41 to the three-dimensional buoy upper surface 11 of the above-described shaking is suppressed, the upper deck 50 on the base base ) Is located, to provide a waterfront buoy waterside deck rod having safety rails (60) is installed on both sides of the top deck (50).

The base base 40 installed on the upper surface of the anti-shaking three-dimensional buoy 10 is made of metals such as steel, plastics, synthetic resins, and the like. It also functions to install and also to distribute the load of the upper deck (50).

Therefore, the base base 40 is not limited to the trident shape as shown in FIG. 4 but may be employed in various ways such as a lattice shape.

The three-dimensional buoy 10 is fixed to the foundation base 40 by using the fastening means 41. The fastening means 41 generally combines two objects to fix the joints, bolts and nuts. It may be employed in various ways.

In addition, the base deck 40 is placed on the top deck 50 to provide a walking space for people to move safely. The top deck 50 generally refers to a flat plate and is made of steel, wood, plastics, and the like.

And, it is apparent to those skilled in the art that the top deck 50 may be provided with a fastening means between the base base 40 and the top deck 50 to be stably coupled to the base base 40. In addition, when the safety handrail 60 supports the upper deck deck 50 from both sides so as not to slip, it may be installed by covering the upper deck deck 50 on the base base 40 without the fastening means.

The base base 40 is fixed to the upper surface of the three-dimensional buoy 10 to which the shaking is suppressed by the fastening means 41, and the upper deck deck 50 is coupled to the buoy-type waterside deck rod that is coupled to the pedestrian's side. For the sake of safety, the top deck 50 may comprise a safety railing 60 on one side or both sides.

Since the safety railing 60 is formed on the side surface of the upper deck 50, the safety railing 60 is separately or two with the base base 40, the upper deck 50 or the three-dimensional buoy 10 This means that it is coupled by the fastening means. The fastening means here can of course be employed in various ways, such as welding, bolt nut, joint. In addition, since the safety railing 60 is formed on the side of the upper deck 50, it can be installed on one or both sides of the upper deck 50.

By connecting a plurality of buoyant waterside deck rods having the configuration as described above is to create a long length waterside deck rod that can be moved by people on the surface of the sea or inner water. Such a waterside deck is resistant to changes in load and wave fluctuations, and thus is used as a waterside deck rod with less waves despite wave fluctuations.

Three-dimensional buoy 10 of the buoyant waterside deck rod is formed to form a ring on the longitudinal side to complete the waterside deck rod is configured to connect the three-dimensional buoy 10 with a rope to each other. It is also advantageous to stabilize the water deck deck rod by fixing the three-dimensional buoys constituting the water deck deck rod, but it can act as a life safety device, especially when the pedestrian falls into the water can hold the rope.

5 is a state diagram showing an embodiment in which the waterside deck rod using the three-dimensional buoy 10 to which the present invention is suppressed is installed.

As shown in FIG. 5, the buoyant waterside deck rod is configured by using the three-dimensional buoy 10 whose shaking is suppressed in the aquatic ecosystem, and the waterside deck rod is completed by connecting a plurality of buoyant waterside deck rods. It will provide a walking path for observing aquatic ecosystems safely on water.

Therefore, even if a large number of people move by using the waterside deck rod, shaking is significantly prevented, and thus, stable and safe water ecosystem learning can be performed.

In addition, even if the number of pedestrians of the waterside deck rod is changed, the wave of the waterside deck rod is prevented by the effect of water pulling the buoy body 14, thereby providing a stable and safe water ecosystem learning site passage.

The three-dimensional buoy 10 according to the present invention can be used as a buoy used in the above-described aquatic ecosystem for learning, buoys in aquaculture farms, buoys for freshwater or sea roads.

It is also used for buoys for floating houses, water decks for dams or lakes.

By applying the buoyant waterside deck rod using the three-dimensional buoy 10 of the present invention to the above fields, it provides a safe and stable waterside deck rod for water quality management, a learning path for aquatic ecosystems, a freshwater or seawater path.

1 is a perspective view of a three-dimensional buoy of the present invention

2 is a cross-sectional view of the three-dimensional buoy of the present invention.

Figure 3 is a state diagram installed on the surface of the three-dimensional buoy that the shaking is suppressed according to the present invention

Figure 4 is an exploded view of a buoyant waterside deck rod using a three-dimensional buoy suppressed shaking in accordance with the present invention

Figure 5 is a state diagram of aquatic ecosystem learning movement using the waterside deck rod using a three-dimensional buoy suppressed shaking in accordance with the present invention

<Description of the symbols for the main parts of the drawings>

10: solid buoy 11: the upper surface of the buoy body

12: lower surface of the buoy body 13: side of the buoy body

15: buoyant body 16: ring

30: cylindrical wing piece

31: connection part of the wing piece 32: end of the wing piece

33: inner space of wing

34: Internal space of wing piece when solid buoy is installed on water 35: End of serrated wing piece

40: base 41: fastening means

50: deck deck 60: safety railing

Claims (5)

In the buoyant water deck deck, which is installed on the water of the inner surface and the sea surface, and configured for human movement, The deck has a three-dimensional buoy (10) formed of a buoy body (14) and the wing piece (30) formed with a ring (16) to tie the rope to the side in the longitudinal direction; A base base 40 fixedly coupled to the upper surface of the three-dimensional buoy 10 by a fastening means; An upper deck 50 coupled to the base base 40; And The upper deck deck 50 is made of a safety railing (60) installed on the side portion, The buoy body 14 includes a buoyancy body therein, and the upper surface 11, the lower surface 12, and the side surface 13 of the buoy body have a planar shape and are connected to the lower curved surface of the buoy body 14. Buoyant waterside deck rod, characterized in that the circumferential length of the connecting portion 31 of the wing piece is smaller than the circumferential length of the wing piece end portion (32). delete The buoyant waterside deck rod according to claim 1, wherein a cylindrical wing piece connected to the lower curved surface of the buoy body (14) forms an acute angle with respect to the water surface, and an end portion of the wing piece has a sawtooth curve shape. The buoyant waterside deck rod according to claim 1, wherein a three-dimensional buoy is connected to each other by connecting a rope to a ring formed at a side of the three-dimensional buoy (10). The buoyant waterfront deck rod according to claim 1, wherein the three-dimensional buoy (10) is selected from one of buoyant compressed resin, plastic, polystyrene, polyurethane, and stainless steel.

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